Characterization and Validation of Telemetric Digital Tachometer based on Hall Effect Sensor

The main objective of this paper is to present a position control design to a DC-motor, where the set-point is externally supplied. The controller is conceived by using vibrational control theory and implemented by just processing the time derivative of a Hall-effect sensor signal. Vibrational control is robust against model uncertainties. Hence, for control design, a simple mathematical model of a DC-Motor is invoked. Then, this controller is realized by utilizing analog electronics via operational amplifiers. In the experimental set-up, one extreme of a flexible beam attached to the motor shaft, and with a permanent magnet fixed on the other end, is constructed. Therefore, the control action consists of externally manipulating the flexible beam rotational position by driving a moveable Hall-effect sensor that is located facing the magnet. The experimental platform results in a low-priced device and is useful for teaching control and electronic topics. Experimental results are evidenced to support the main paper contribution.

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Improving Turret Control on Military Vehicles

Volume 10: Mechanical Systems and Control, Parts A and B ◽

10.1115/imece2009-11821 ◽

2009 ◽

Author(s):

Thomas W. Anderson ◽

Nathaniel A. Clark ◽

Wesley E. Kotz ◽

Briana D. Stremick ◽

O¨zer Arnas ◽

...

Keyword(s):

Hall Effect ◽

Output Voltage ◽

Magnetic Force ◽

Electric Signal ◽

Similar Response ◽

Hall Effect Sensor ◽

Military Vehicles ◽

Tactical Vehicle ◽

The Magnetic Field ◽

Mechanical Assistance

Recent additions of armor have made light tactical vehicle turrets heavy enough that mechanical assistance is required for them to rotate. The Army’s solution is the Battery Powered Motorized Traversing Unit (BPMTU) which uses a joystick to traverse the turret. Use of the joystick distracts the gunner and prevents the gunner from continuously engaging the target while rotating the turret. This paper presents a modification to the weapon mount that allows the turret to be controlled by the position of the weapon itself and emphasizes the design process used to develop the inovation. With this design, the gunner can now maintain contact with a target, while rotating the turret, without fiddling with the joystick. The Weapon Activated and Controlled Turret (WACT) consists of two primary components; the bottom component is stationary relative to the turret and contains a Hall effect sensor and the top component rotates with the weapon and holds a linear magnet. As the position of the sensor relative to the magnet changes, the corresponding strength of the magnetic field also varies. This change in magnetic force induces a similar response in the output voltage of the Hall effect sensor, effectively translating rotational motion into an electric signal able to control the turret motor.

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Hall-effect sensor positional transducer

10.1117/12.360354 ◽

1999 ◽

Author(s):

Carlo A. Avizzano ◽

Diego Ferrazzin ◽

Giuseppe M. Prisco ◽

Massimo Bergamasco

Keyword(s):

Hall Effect ◽

Hall Effect Sensor

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Hall-Effect Sensor Technique for No Induced Voltage in AC Magnetic Field Measurements Without Current Spinning

IEEE Sensors Journal ◽

10.1109/jsen.2021.3130527 ◽

2021 ◽

pp. 1-1

Author(s):

A. V. Lalwani ◽

A. S. Yalamarthy ◽

H. S. Alpert ◽

M. A. Holliday ◽

S. R. Eisner ◽

...

Keyword(s):

Magnetic Field ◽

Hall Effect ◽

Field Measurements ◽

Induced Voltage ◽

Ac Magnetic Field ◽

Hall Effect Sensor ◽

Sensor Technique ◽

Magnetic Field Measurements

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Real-time condition monitoring of a gearbox using Hall effect sensor

2021 4th Biennial International Conference on Nascent Technologies in Engineering (ICNTE) ◽

10.1109/icnte51185.2021.9487667 ◽

2021 ◽

Author(s):

Nitesh P. Yelve ◽

Yohann Lobo ◽

Aditi Deogire ◽

Joel Mathew Varghese ◽

Mohammed Talha

Keyword(s):

Hall Effect ◽

Real Time ◽

Condition Monitoring ◽

Time Condition ◽

Hall Effect Sensor

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2D In-Plane Sensitive Hall-Effect Sensor

Proceedings ◽

10.3390/proceedings2130711 ◽

2018 ◽

Vol 2 (13) ◽

pp. 711

Author(s):

Siya Lozanova ◽

Ivan Kolev ◽

Avgust Ivanov ◽

Chavdar Roumenin

Keyword(s):

Hall Effect ◽

Signal To Noise Ratio ◽

Hall Effect Sensor ◽

Orthogonal Components ◽

The Mean ◽

The Cross ◽

The Magnetic Field ◽

Outer Contact ◽

Hall Elements ◽

Ic Technology

A new 2D (two-dimensional) in-plane sensitive Hall-effect sensor comprising two identical n-Si Greek-crosses is presented. Each of the crosses contains one central square contact and, symmetrically to each of their four sides, an outer contact is available. Outer electrode from one configuration is connected with the respective opposite contact from the other configuration, thus forming four parallel three-contact (3C) Hall elements. These original connections provide pairs of opposite supply currents in each of the cross-Hall structure. Also the obligatory load resistors in the outer contacts of 3С Hall elements are replaced by internal resistances of crosses themselves. The samples have been implemented by IC technology, using four masks. The magnetic field is parallel to the structures’ plane. The couples of opposite contacts of each Greek-cross are the outputs for the two orthogonal components of the magnetic vector at sensitivities S ≈ 115 V/AT whereas the cross-talk is very promising, reaching no more than 2.4%. The mean lowest detected magnetic induction B at a supply current Is = 3 mA over the frequency range f ≤ 500 Hz at a signal to noise ratio equal to unity, is Bmin ≈ 14 μT.

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Semi-Precise Analytical Method for Investigating the Liftoff Variation on the Hall Sensor in Metal Defect Sensing

Sensors ◽

10.3390/s21165539 ◽

2021 ◽

Vol 21 (16) ◽

pp. 5539

Author(s):

Ali Azad ◽

Jong-Jae Lee ◽

Namgyu Kim

Keyword(s):

Numerical Methods ◽

Hall Effect ◽

Numerical Method ◽

Surface Defects ◽

Simulation Method ◽

Hall Sensor ◽

Induced Current ◽

Element Analysis ◽

Hall Effect Sensor ◽

Conventional Numerical Method

Hall-effect sensors are used to detect metal surface defects both experimentally and numerically. The gap between the specimen and the sensor, called the liftoff, is assumed to remain constant, while a slight misplacement of a sample may lead to incorrect measurements by the Hall-effect sensor. This paper proposes a numerical simulation method to mitigate the liftoff issue. Owing to the complexity of conducting precise finite-element analysis, rather than obtaining the induced current in the Hall sensor, only the magnetic flux leakage is obtained. Thus, to achieve a better approximation, a numerical method capable of obtaining the induced current density in the circumferential direction in terms of the inspection direction is also proposed. Signals of the conventional and proposed approximate numerical methods affected by the sensor liftoff variation were obtained and compared. For small liftoffs, both conventional and proposed numerical methods could identify notch defects, while as the liftoff increased, no defect could be identified using the conventional numerical method. Furthermore, experiments were performed using a variety of liftoff configurations. Based on the results, considering the threshold of the conventional numerical method, defects were detected for greater liftoffs, but misdetection did not occur.

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